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-rw-r--r--thirdparty/bullet/src/BulletInverseDynamics/details/IDEigenInterface.hpp36
-rw-r--r--thirdparty/bullet/src/BulletInverseDynamics/details/IDLinearMathInterface.hpp172
-rw-r--r--thirdparty/bullet/src/BulletInverseDynamics/details/IDMatVec.hpp415
-rw-r--r--thirdparty/bullet/src/BulletInverseDynamics/details/MultiBodyTreeImpl.cpp1028
-rw-r--r--thirdparty/bullet/src/BulletInverseDynamics/details/MultiBodyTreeImpl.hpp283
-rw-r--r--thirdparty/bullet/src/BulletInverseDynamics/details/MultiBodyTreeInitCache.cpp113
-rw-r--r--thirdparty/bullet/src/BulletInverseDynamics/details/MultiBodyTreeInitCache.hpp109
7 files changed, 0 insertions, 2156 deletions
diff --git a/thirdparty/bullet/src/BulletInverseDynamics/details/IDEigenInterface.hpp b/thirdparty/bullet/src/BulletInverseDynamics/details/IDEigenInterface.hpp
deleted file mode 100644
index 836395cea2..0000000000
--- a/thirdparty/bullet/src/BulletInverseDynamics/details/IDEigenInterface.hpp
+++ /dev/null
@@ -1,36 +0,0 @@
-#ifndef INVDYNEIGENINTERFACE_HPP_
-#define INVDYNEIGENINTERFACE_HPP_
-#include "../IDConfig.hpp"
-namespace btInverseDynamics {
-
-#define BT_ID_HAVE_MAT3X
-
-#ifdef BT_USE_DOUBLE_PRECISION
-typedef Eigen::Matrix<double, Eigen::Dynamic, 1, Eigen::DontAlign> vecx;
-typedef Eigen::Matrix<double, 3, 1, Eigen::DontAlign> vec3;
-typedef Eigen::Matrix<double, 3, 3, Eigen::DontAlign> mat33;
-typedef Eigen::Matrix<double, Eigen::Dynamic, Eigen::Dynamic, Eigen::DontAlign> matxx;
-typedef Eigen::Matrix<double, 3, Eigen::Dynamic, Eigen::DontAlign> mat3x;
-#else
-typedef Eigen::Matrix<float, Eigen::Dynamic, 1, Eigen::DontAlign> vecx;
-typedef Eigen::Matrix<float, 3, 1, Eigen::DontAlign> vec3;
-typedef Eigen::Matrix<float, 3, 3, Eigen::DontAlign> mat33;
-typedef Eigen::Matrix<float, Eigen::Dynamic, Eigen::Dynamic, Eigen::DontAlign> matxx;
-typedef Eigen::Matrix<float, 3, Eigen::Dynamic, Eigen::DontAlign> mat3x;
-#endif
-
-inline void resize(mat3x &m, Eigen::Index size) {
- m.resize(3, size);
- m.setZero();
-}
-
-inline void setMatxxElem(const idArrayIdx row, const idArrayIdx col, const idScalar val, matxx*m){
- (*m)(row, col) = val;
-}
-
-inline void setMat3xElem(const idArrayIdx row, const idArrayIdx col, const idScalar val, mat3x*m){
- (*m)(row, col) = val;
-}
-
-}
-#endif // INVDYNEIGENINTERFACE_HPP_
diff --git a/thirdparty/bullet/src/BulletInverseDynamics/details/IDLinearMathInterface.hpp b/thirdparty/bullet/src/BulletInverseDynamics/details/IDLinearMathInterface.hpp
deleted file mode 100644
index 5bb4a33bdd..0000000000
--- a/thirdparty/bullet/src/BulletInverseDynamics/details/IDLinearMathInterface.hpp
+++ /dev/null
@@ -1,172 +0,0 @@
-#ifndef IDLINEARMATHINTERFACE_HPP_
-#define IDLINEARMATHINTERFACE_HPP_
-
-#include <cstdlib>
-
-#include "../IDConfig.hpp"
-
-#include "../../LinearMath/btMatrix3x3.h"
-#include "../../LinearMath/btVector3.h"
-#include "../../LinearMath/btMatrixX.h"
-#define BT_ID_HAVE_MAT3X
-
-namespace btInverseDynamics {
-class vec3;
-class vecx;
-class mat33;
-typedef btMatrixX<idScalar> matxx;
-
-class vec3 : public btVector3 {
-public:
- vec3() : btVector3() {}
- vec3(const btVector3& btv) { *this = btv; }
- idScalar& operator()(int i) { return (*this)[i]; }
- const idScalar& operator()(int i) const { return (*this)[i]; }
- int size() const { return 3; }
- const vec3& operator=(const btVector3& rhs) {
- *static_cast<btVector3*>(this) = rhs;
- return *this;
- }
-};
-
-class mat33 : public btMatrix3x3 {
-public:
- mat33() : btMatrix3x3() {}
- mat33(const btMatrix3x3& btm) { *this = btm; }
- idScalar& operator()(int i, int j) { return (*this)[i][j]; }
- const idScalar& operator()(int i, int j) const { return (*this)[i][j]; }
- const mat33& operator=(const btMatrix3x3& rhs) {
- *static_cast<btMatrix3x3*>(this) = rhs;
- return *this;
- }
- friend mat33 operator*(const idScalar& s, const mat33& a);
- friend mat33 operator/(const mat33& a, const idScalar& s);
-};
-
-inline mat33 operator/(const mat33& a, const idScalar& s) { return a * (1.0 / s); }
-
-inline mat33 operator*(const idScalar& s, const mat33& a) { return a * s; }
-
-class vecx : public btVectorX<idScalar> {
-public:
- vecx(int size) : btVectorX(size) {}
- const vecx& operator=(const btVectorX<idScalar>& rhs) {
- *static_cast<btVectorX*>(this) = rhs;
- return *this;
- }
-
- idScalar& operator()(int i) { return (*this)[i]; }
- const idScalar& operator()(int i) const { return (*this)[i]; }
-
- friend vecx operator*(const vecx& a, const idScalar& s);
- friend vecx operator*(const idScalar& s, const vecx& a);
-
- friend vecx operator+(const vecx& a, const vecx& b);
- friend vecx operator-(const vecx& a, const vecx& b);
- friend vecx operator/(const vecx& a, const idScalar& s);
-};
-
-inline vecx operator*(const vecx& a, const idScalar& s) {
- vecx result(a.size());
- for (int i = 0; i < result.size(); i++) {
- result(i) = a(i) * s;
- }
- return result;
-}
-inline vecx operator*(const idScalar& s, const vecx& a) { return a * s; }
-inline vecx operator+(const vecx& a, const vecx& b) {
- vecx result(a.size());
- // TODO: error handling for a.size() != b.size()??
- if (a.size() != b.size()) {
- error_message("size missmatch. a.size()= %d, b.size()= %d\n", a.size(), b.size());
- abort();
- }
- for (int i = 0; i < a.size(); i++) {
- result(i) = a(i) + b(i);
- }
-
- return result;
-}
-
-inline vecx operator-(const vecx& a, const vecx& b) {
- vecx result(a.size());
- // TODO: error handling for a.size() != b.size()??
- if (a.size() != b.size()) {
- error_message("size missmatch. a.size()= %d, b.size()= %d\n", a.size(), b.size());
- abort();
- }
- for (int i = 0; i < a.size(); i++) {
- result(i) = a(i) - b(i);
- }
- return result;
-}
-inline vecx operator/(const vecx& a, const idScalar& s) {
- vecx result(a.size());
- for (int i = 0; i < result.size(); i++) {
- result(i) = a(i) / s;
- }
-
- return result;
-}
-
-// use btMatrixX to implement 3xX matrix
-class mat3x : public matxx {
-public:
- mat3x(){}
- mat3x(const mat3x&rhs) {
- matxx::resize(rhs.rows(), rhs.cols());
- *this = rhs;
- }
- mat3x(int rows, int cols): matxx(3,cols) {
- }
- void operator=(const mat3x& rhs) {
- if (m_cols != rhs.m_cols) {
- error_message("size missmatch, cols= %d but rhs.cols= %d\n", cols(), rhs.cols());
- abort();
- }
- for(int i=0;i<rows();i++) {
- for(int k=0;k<cols();k++) {
- setElem(i,k,rhs(i,k));
- }
- }
- }
- void setZero() {
- matxx::setZero();
- }
-};
-
-
-inline vec3 operator*(const mat3x& a, const vecx& b) {
- vec3 result;
- if (a.cols() != b.size()) {
- error_message("size missmatch. a.cols()= %d, b.size()= %d\n", a.cols(), b.size());
- abort();
- }
- result(0)=0.0;
- result(1)=0.0;
- result(2)=0.0;
- for(int i=0;i<b.size();i++) {
- for(int k=0;k<3;k++) {
- result(k)+=a(k,i)*b(i);
- }
- }
- return result;
-}
-
-
-inline void resize(mat3x &m, idArrayIdx size) {
- m.resize(3, size);
- m.setZero();
-}
-
-inline void setMatxxElem(const idArrayIdx row, const idArrayIdx col, const idScalar val, matxx*m){
- m->setElem(row, col, val);
-}
-
-inline void setMat3xElem(const idArrayIdx row, const idArrayIdx col, const idScalar val, mat3x*m){
- m->setElem(row, col, val);
-}
-
-}
-
-#endif // IDLINEARMATHINTERFACE_HPP_
diff --git a/thirdparty/bullet/src/BulletInverseDynamics/details/IDMatVec.hpp b/thirdparty/bullet/src/BulletInverseDynamics/details/IDMatVec.hpp
deleted file mode 100644
index 4d3f6c87e9..0000000000
--- a/thirdparty/bullet/src/BulletInverseDynamics/details/IDMatVec.hpp
+++ /dev/null
@@ -1,415 +0,0 @@
-/// @file Built-In Matrix-Vector functions
-#ifndef IDMATVEC_HPP_
-#define IDMATVEC_HPP_
-
-#include <cstdlib>
-
-#include "../IDConfig.hpp"
-#define BT_ID_HAVE_MAT3X
-
-namespace btInverseDynamics {
-class vec3;
-class vecx;
-class mat33;
-class matxx;
-class mat3x;
-
-/// This is a very basic implementation to enable stand-alone use of the library.
-/// The implementation is not really optimized and misses many features that you would
-/// want from a "fully featured" linear math library.
-class vec3 {
-public:
- idScalar& operator()(int i) { return m_data[i]; }
- const idScalar& operator()(int i) const { return m_data[i]; }
- const int size() const { return 3; }
- const vec3& operator=(const vec3& rhs);
- const vec3& operator+=(const vec3& b);
- const vec3& operator-=(const vec3& b);
- vec3 cross(const vec3& b) const;
- idScalar dot(const vec3& b) const;
-
- friend vec3 operator*(const mat33& a, const vec3& b);
- friend vec3 operator*(const vec3& a, const idScalar& s);
- friend vec3 operator*(const idScalar& s, const vec3& a);
-
- friend vec3 operator+(const vec3& a, const vec3& b);
- friend vec3 operator-(const vec3& a, const vec3& b);
- friend vec3 operator/(const vec3& a, const idScalar& s);
-
-private:
- idScalar m_data[3];
-};
-
-class mat33 {
-public:
- idScalar& operator()(int i, int j) { return m_data[3 * i + j]; }
- const idScalar& operator()(int i, int j) const { return m_data[3 * i + j]; }
- const mat33& operator=(const mat33& rhs);
- mat33 transpose() const;
- const mat33& operator+=(const mat33& b);
- const mat33& operator-=(const mat33& b);
-
- friend mat33 operator*(const mat33& a, const mat33& b);
- friend vec3 operator*(const mat33& a, const vec3& b);
- friend mat33 operator*(const mat33& a, const idScalar& s);
- friend mat33 operator*(const idScalar& s, const mat33& a);
- friend mat33 operator+(const mat33& a, const mat33& b);
- friend mat33 operator-(const mat33& a, const mat33& b);
- friend mat33 operator/(const mat33& a, const idScalar& s);
-
-private:
- // layout is [0,1,2;3,4,5;6,7,8]
- idScalar m_data[9];
-};
-
-class vecx {
-public:
- vecx(int size) : m_size(size) {
- m_data = static_cast<idScalar*>(idMalloc(sizeof(idScalar) * size));
- }
- ~vecx() { idFree(m_data); }
- const vecx& operator=(const vecx& rhs);
- idScalar& operator()(int i) { return m_data[i]; }
- const idScalar& operator()(int i) const { return m_data[i]; }
- const int& size() const { return m_size; }
-
- friend vecx operator*(const vecx& a, const idScalar& s);
- friend vecx operator*(const idScalar& s, const vecx& a);
-
- friend vecx operator+(const vecx& a, const vecx& b);
- friend vecx operator-(const vecx& a, const vecx& b);
- friend vecx operator/(const vecx& a, const idScalar& s);
-
-private:
- int m_size;
- idScalar* m_data;
-};
-
-class matxx {
-public:
- matxx() {
- m_data = 0x0;
- m_cols=0;
- m_rows=0;
- }
- matxx(int rows, int cols) : m_rows(rows), m_cols(cols) {
- m_data = static_cast<idScalar*>(idMalloc(sizeof(idScalar) * rows * cols));
- }
- ~matxx() { idFree(m_data); }
- idScalar& operator()(int row, int col) { return m_data[row * m_cols + col]; }
- const idScalar& operator()(int row, int col) const { return m_data[row * m_cols + col]; }
- const int& rows() const { return m_rows; }
- const int& cols() const { return m_cols; }
-
-private:
- int m_rows;
- int m_cols;
- idScalar* m_data;
-};
-
-class mat3x {
-public:
- mat3x() {
- m_data = 0x0;
- m_cols=0;
- }
- mat3x(const mat3x&rhs) {
- m_cols=rhs.m_cols;
- allocate();
- *this = rhs;
- }
- mat3x(int rows, int cols): m_cols(cols) {
- allocate();
- };
- void operator=(const mat3x& rhs) {
- if (m_cols != rhs.m_cols) {
- error_message("size missmatch, cols= %d but rhs.cols= %d\n", cols(), rhs.cols());
- abort();
- }
- for(int i=0;i<3*m_cols;i++) {
- m_data[i] = rhs.m_data[i];
- }
- }
-
- ~mat3x() {
- free();
- }
- idScalar& operator()(int row, int col) { return m_data[row * m_cols + col]; }
- const idScalar& operator()(int row, int col) const { return m_data[row * m_cols + col]; }
- int rows() const { return m_rows; }
- const int& cols() const { return m_cols; }
- void resize(int rows, int cols) {
- m_cols=cols;
- free();
- allocate();
- }
- void setZero() {
- memset(m_data,0x0,sizeof(idScalar)*m_rows*m_cols);
- }
- // avoid operators that would allocate -- use functions sub/add/mul in IDMath.hpp instead
-private:
- void allocate(){m_data = static_cast<idScalar*>(idMalloc(sizeof(idScalar) * m_rows * m_cols));}
- void free() { idFree(m_data);}
- enum {m_rows=3};
- int m_cols;
- idScalar* m_data;
-};
-
-inline void resize(mat3x &m, idArrayIdx size) {
- m.resize(3, size);
- m.setZero();
-}
-
-//////////////////////////////////////////////////
-// Implementations
-inline const vec3& vec3::operator=(const vec3& rhs) {
- if (&rhs != this) {
- memcpy(m_data, rhs.m_data, 3 * sizeof(idScalar));
- }
- return *this;
-}
-
-inline vec3 vec3::cross(const vec3& b) const {
- vec3 result;
- result.m_data[0] = m_data[1] * b.m_data[2] - m_data[2] * b.m_data[1];
- result.m_data[1] = m_data[2] * b.m_data[0] - m_data[0] * b.m_data[2];
- result.m_data[2] = m_data[0] * b.m_data[1] - m_data[1] * b.m_data[0];
-
- return result;
-}
-
-inline idScalar vec3::dot(const vec3& b) const {
- return m_data[0] * b.m_data[0] + m_data[1] * b.m_data[1] + m_data[2] * b.m_data[2];
-}
-
-inline const mat33& mat33::operator=(const mat33& rhs) {
- if (&rhs != this) {
- memcpy(m_data, rhs.m_data, 9 * sizeof(idScalar));
- }
- return *this;
-}
-inline mat33 mat33::transpose() const {
- mat33 result;
- result.m_data[0] = m_data[0];
- result.m_data[1] = m_data[3];
- result.m_data[2] = m_data[6];
- result.m_data[3] = m_data[1];
- result.m_data[4] = m_data[4];
- result.m_data[5] = m_data[7];
- result.m_data[6] = m_data[2];
- result.m_data[7] = m_data[5];
- result.m_data[8] = m_data[8];
-
- return result;
-}
-
-inline mat33 operator*(const mat33& a, const mat33& b) {
- mat33 result;
- result.m_data[0] =
- a.m_data[0] * b.m_data[0] + a.m_data[1] * b.m_data[3] + a.m_data[2] * b.m_data[6];
- result.m_data[1] =
- a.m_data[0] * b.m_data[1] + a.m_data[1] * b.m_data[4] + a.m_data[2] * b.m_data[7];
- result.m_data[2] =
- a.m_data[0] * b.m_data[2] + a.m_data[1] * b.m_data[5] + a.m_data[2] * b.m_data[8];
- result.m_data[3] =
- a.m_data[3] * b.m_data[0] + a.m_data[4] * b.m_data[3] + a.m_data[5] * b.m_data[6];
- result.m_data[4] =
- a.m_data[3] * b.m_data[1] + a.m_data[4] * b.m_data[4] + a.m_data[5] * b.m_data[7];
- result.m_data[5] =
- a.m_data[3] * b.m_data[2] + a.m_data[4] * b.m_data[5] + a.m_data[5] * b.m_data[8];
- result.m_data[6] =
- a.m_data[6] * b.m_data[0] + a.m_data[7] * b.m_data[3] + a.m_data[8] * b.m_data[6];
- result.m_data[7] =
- a.m_data[6] * b.m_data[1] + a.m_data[7] * b.m_data[4] + a.m_data[8] * b.m_data[7];
- result.m_data[8] =
- a.m_data[6] * b.m_data[2] + a.m_data[7] * b.m_data[5] + a.m_data[8] * b.m_data[8];
-
- return result;
-}
-
-inline const mat33& mat33::operator+=(const mat33& b) {
- for (int i = 0; i < 9; i++) {
- m_data[i] += b.m_data[i];
- }
-
- return *this;
-}
-
-inline const mat33& mat33::operator-=(const mat33& b) {
- for (int i = 0; i < 9; i++) {
- m_data[i] -= b.m_data[i];
- }
- return *this;
-}
-
-inline vec3 operator*(const mat33& a, const vec3& b) {
- vec3 result;
-
- result.m_data[0] =
- a.m_data[0] * b.m_data[0] + a.m_data[1] * b.m_data[1] + a.m_data[2] * b.m_data[2];
- result.m_data[1] =
- a.m_data[3] * b.m_data[0] + a.m_data[4] * b.m_data[1] + a.m_data[5] * b.m_data[2];
- result.m_data[2] =
- a.m_data[6] * b.m_data[0] + a.m_data[7] * b.m_data[1] + a.m_data[8] * b.m_data[2];
-
- return result;
-}
-
-inline const vec3& vec3::operator+=(const vec3& b) {
- for (int i = 0; i < 3; i++) {
- m_data[i] += b.m_data[i];
- }
- return *this;
-}
-
-inline const vec3& vec3::operator-=(const vec3& b) {
- for (int i = 0; i < 3; i++) {
- m_data[i] -= b.m_data[i];
- }
- return *this;
-}
-
-inline mat33 operator*(const mat33& a, const idScalar& s) {
- mat33 result;
- for (int i = 0; i < 9; i++) {
- result.m_data[i] = a.m_data[i] * s;
- }
- return result;
-}
-
-inline mat33 operator*(const idScalar& s, const mat33& a) { return a * s; }
-
-inline vec3 operator*(const vec3& a, const idScalar& s) {
- vec3 result;
- for (int i = 0; i < 3; i++) {
- result.m_data[i] = a.m_data[i] * s;
- }
- return result;
-}
-inline vec3 operator*(const idScalar& s, const vec3& a) { return a * s; }
-
-inline mat33 operator+(const mat33& a, const mat33& b) {
- mat33 result;
- for (int i = 0; i < 9; i++) {
- result.m_data[i] = a.m_data[i] + b.m_data[i];
- }
- return result;
-}
-inline vec3 operator+(const vec3& a, const vec3& b) {
- vec3 result;
- for (int i = 0; i < 3; i++) {
- result.m_data[i] = a.m_data[i] + b.m_data[i];
- }
- return result;
-}
-
-inline mat33 operator-(const mat33& a, const mat33& b) {
- mat33 result;
- for (int i = 0; i < 9; i++) {
- result.m_data[i] = a.m_data[i] - b.m_data[i];
- }
- return result;
-}
-inline vec3 operator-(const vec3& a, const vec3& b) {
- vec3 result;
- for (int i = 0; i < 3; i++) {
- result.m_data[i] = a.m_data[i] - b.m_data[i];
- }
- return result;
-}
-
-inline mat33 operator/(const mat33& a, const idScalar& s) {
- mat33 result;
- for (int i = 0; i < 9; i++) {
- result.m_data[i] = a.m_data[i] / s;
- }
- return result;
-}
-
-inline vec3 operator/(const vec3& a, const idScalar& s) {
- vec3 result;
- for (int i = 0; i < 3; i++) {
- result.m_data[i] = a.m_data[i] / s;
- }
- return result;
-}
-
-inline const vecx& vecx::operator=(const vecx& rhs) {
- if (size() != rhs.size()) {
- error_message("size missmatch, size()= %d but rhs.size()= %d\n", size(), rhs.size());
- abort();
- }
- if (&rhs != this) {
- memcpy(m_data, rhs.m_data, rhs.size() * sizeof(idScalar));
- }
- return *this;
-}
-inline vecx operator*(const vecx& a, const idScalar& s) {
- vecx result(a.size());
- for (int i = 0; i < result.size(); i++) {
- result.m_data[i] = a.m_data[i] * s;
- }
- return result;
-}
-inline vecx operator*(const idScalar& s, const vecx& a) { return a * s; }
-inline vecx operator+(const vecx& a, const vecx& b) {
- vecx result(a.size());
- // TODO: error handling for a.size() != b.size()??
- if (a.size() != b.size()) {
- error_message("size missmatch. a.size()= %d, b.size()= %d\n", a.size(), b.size());
- abort();
- }
- for (int i = 0; i < a.size(); i++) {
- result.m_data[i] = a.m_data[i] + b.m_data[i];
- }
-
- return result;
-}
-inline vecx operator-(const vecx& a, const vecx& b) {
- vecx result(a.size());
- // TODO: error handling for a.size() != b.size()??
- if (a.size() != b.size()) {
- error_message("size missmatch. a.size()= %d, b.size()= %d\n", a.size(), b.size());
- abort();
- }
- for (int i = 0; i < a.size(); i++) {
- result.m_data[i] = a.m_data[i] - b.m_data[i];
- }
- return result;
-}
-inline vecx operator/(const vecx& a, const idScalar& s) {
- vecx result(a.size());
- for (int i = 0; i < result.size(); i++) {
- result.m_data[i] = a.m_data[i] / s;
- }
-
- return result;
-}
-
-inline vec3 operator*(const mat3x& a, const vecx& b) {
- vec3 result;
- if (a.cols() != b.size()) {
- error_message("size missmatch. a.cols()= %d, b.size()= %d\n", a.cols(), b.size());
- abort();
- }
- result(0)=0.0;
- result(1)=0.0;
- result(2)=0.0;
- for(int i=0;i<b.size();i++) {
- for(int k=0;k<3;k++) {
- result(k)+=a(k,i)*b(i);
- }
- }
- return result;
-}
-
-inline void setMatxxElem(const idArrayIdx row, const idArrayIdx col, const idScalar val, matxx*m){
- (*m)(row, col) = val;
-}
-
-inline void setMat3xElem(const idArrayIdx row, const idArrayIdx col, const idScalar val, mat3x*m){
- (*m)(row, col) = val;
-}
-
-} // namespace btInverseDynamcis
-#endif
diff --git a/thirdparty/bullet/src/BulletInverseDynamics/details/MultiBodyTreeImpl.cpp b/thirdparty/bullet/src/BulletInverseDynamics/details/MultiBodyTreeImpl.cpp
deleted file mode 100644
index b35c55df61..0000000000
--- a/thirdparty/bullet/src/BulletInverseDynamics/details/MultiBodyTreeImpl.cpp
+++ /dev/null
@@ -1,1028 +0,0 @@
-#include "MultiBodyTreeImpl.hpp"
-
-namespace btInverseDynamics {
-
-MultiBodyTree::MultiBodyImpl::MultiBodyImpl(int num_bodies_, int num_dofs_)
- : m_num_bodies(num_bodies_), m_num_dofs(num_dofs_)
-#if (defined BT_ID_HAVE_MAT3X) && (defined BT_ID_WITH_JACOBIANS)
- ,m_m3x(3,m_num_dofs)
-#endif
-{
-
-#if (defined BT_ID_HAVE_MAT3X) && (defined BT_ID_WITH_JACOBIANS)
- resize(m_m3x,m_num_dofs);
-#endif
- m_body_list.resize(num_bodies_);
- m_parent_index.resize(num_bodies_);
- m_child_indices.resize(num_bodies_);
- m_user_int.resize(num_bodies_);
- m_user_ptr.resize(num_bodies_);
-
- m_world_gravity(0) = 0.0;
- m_world_gravity(1) = 0.0;
- m_world_gravity(2) = -9.8;
-}
-
-const char *MultiBodyTree::MultiBodyImpl::jointTypeToString(const JointType &type) const {
- switch (type) {
- case FIXED:
- return "fixed";
- case REVOLUTE:
- return "revolute";
- case PRISMATIC:
- return "prismatic";
- case FLOATING:
- return "floating";
- }
- return "error: invalid";
-}
-
-inline void indent(const int &level) {
- for (int j = 0; j < level; j++)
- id_printf(" "); // indent
-}
-
-void MultiBodyTree::MultiBodyImpl::printTree() {
- id_printf("body %.2d[%s]: root\n", 0, jointTypeToString(m_body_list[0].m_joint_type));
- printTree(0, 0);
-}
-
-void MultiBodyTree::MultiBodyImpl::printTreeData() {
- for (idArrayIdx i = 0; i < m_body_list.size(); i++) {
- RigidBody &body = m_body_list[i];
- id_printf("body: %d\n", static_cast<int>(i));
- id_printf("type: %s\n", jointTypeToString(body.m_joint_type));
- id_printf("q_index= %d\n", body.m_q_index);
- id_printf("Jac_JR= [%f;%f;%f]\n", body.m_Jac_JR(0), body.m_Jac_JR(1), body.m_Jac_JR(2));
- id_printf("Jac_JT= [%f;%f;%f]\n", body.m_Jac_JT(0), body.m_Jac_JT(1), body.m_Jac_JT(2));
-
- id_printf("mass = %f\n", body.m_mass);
- id_printf("mass * com = [%f %f %f]\n", body.m_body_mass_com(0), body.m_body_mass_com(1),
- body.m_body_mass_com(2));
- id_printf("I_o= [%f %f %f;\n"
- " %f %f %f;\n"
- " %f %f %f]\n",
- body.m_body_I_body(0, 0), body.m_body_I_body(0, 1), body.m_body_I_body(0, 2),
- body.m_body_I_body(1, 0), body.m_body_I_body(1, 1), body.m_body_I_body(1, 2),
- body.m_body_I_body(2, 0), body.m_body_I_body(2, 1), body.m_body_I_body(2, 2));
-
- id_printf("parent_pos_parent_body_ref= [%f %f %f]\n", body.m_parent_pos_parent_body_ref(0),
- body.m_parent_pos_parent_body_ref(1), body.m_parent_pos_parent_body_ref(2));
- }
-}
-int MultiBodyTree::MultiBodyImpl::bodyNumDoFs(const JointType &type) const {
- switch (type) {
- case FIXED:
- return 0;
- case REVOLUTE:
- case PRISMATIC:
- return 1;
- case FLOATING:
- return 6;
- }
- error_message("unknown joint type %d\n", type);
- return 0;
-}
-
-void MultiBodyTree::MultiBodyImpl::printTree(int index, int indentation) {
- // this is adapted from URDF2Bullet.
- // TODO: fix this and print proper graph (similar to git --log --graph)
- int num_children = m_child_indices[index].size();
-
- indentation += 2;
- int count = 0;
-
- for (int i = 0; i < num_children; i++) {
- int child_index = m_child_indices[index][i];
- indent(indentation);
- id_printf("body %.2d[%s]: %.2d is child no. %d (qi= %d .. %d) \n", index,
- jointTypeToString(m_body_list[index].m_joint_type), child_index, (count++) + 1,
- m_body_list[index].m_q_index,
- m_body_list[index].m_q_index + bodyNumDoFs(m_body_list[index].m_joint_type));
- // first grandchild
- printTree(child_index, indentation);
- }
-}
-
-int MultiBodyTree::MultiBodyImpl::setGravityInWorldFrame(const vec3 &gravity) {
- m_world_gravity = gravity;
- return 0;
-}
-
-int MultiBodyTree::MultiBodyImpl::generateIndexSets() {
- m_body_revolute_list.resize(0);
- m_body_prismatic_list.resize(0);
- int q_index = 0;
- for (idArrayIdx i = 0; i < m_body_list.size(); i++) {
- RigidBody &body = m_body_list[i];
- body.m_q_index = -1;
- switch (body.m_joint_type) {
- case REVOLUTE:
- m_body_revolute_list.push_back(i);
- body.m_q_index = q_index;
- q_index++;
- break;
- case PRISMATIC:
- m_body_prismatic_list.push_back(i);
- body.m_q_index = q_index;
- q_index++;
- break;
- case FIXED:
- // do nothing
- break;
- case FLOATING:
- m_body_floating_list.push_back(i);
- body.m_q_index = q_index;
- q_index += 6;
- break;
- default:
- error_message("unsupported joint type %d\n", body.m_joint_type);
- return -1;
- }
- }
- // sanity check
- if (q_index != m_num_dofs) {
- error_message("internal error, q_index= %d but num_dofs %d\n", q_index, m_num_dofs);
- return -1;
- }
-
- m_child_indices.resize(m_body_list.size());
-
- for (idArrayIdx child = 1; child < m_parent_index.size(); child++) {
- const int &parent = m_parent_index[child];
- if (parent >= 0 && parent < (static_cast<int>(m_parent_index.size()) - 1)) {
- m_child_indices[parent].push_back(child);
- } else {
- if (-1 == parent) {
- // multiple bodies are directly linked to the environment, ie, not a single root
- error_message("building index sets parent(%zu)= -1 (multiple roots)\n", child);
- } else {
- // should never happen
- error_message(
- "building index sets. parent_index[%zu]= %d, but m_parent_index.size()= %d\n",
- child, parent, static_cast<int>(m_parent_index.size()));
- }
- return -1;
- }
- }
-
- return 0;
-}
-
-void MultiBodyTree::MultiBodyImpl::calculateStaticData() {
- // relative kinematics that are not a function of q, u, dot_u
- for (idArrayIdx i = 0; i < m_body_list.size(); i++) {
- RigidBody &body = m_body_list[i];
- switch (body.m_joint_type) {
- case REVOLUTE:
- body.m_parent_vel_rel(0) = 0;
- body.m_parent_vel_rel(1) = 0;
- body.m_parent_vel_rel(2) = 0;
- body.m_parent_acc_rel(0) = 0;
- body.m_parent_acc_rel(1) = 0;
- body.m_parent_acc_rel(2) = 0;
- body.m_parent_pos_parent_body = body.m_parent_pos_parent_body_ref;
- break;
- case PRISMATIC:
- body.m_body_T_parent = body.m_body_T_parent_ref;
- body.m_parent_Jac_JT = body.m_body_T_parent_ref.transpose() * body.m_Jac_JT;
- body.m_body_ang_vel_rel(0) = 0;
- body.m_body_ang_vel_rel(1) = 0;
- body.m_body_ang_vel_rel(2) = 0;
- body.m_body_ang_acc_rel(0) = 0;
- body.m_body_ang_acc_rel(1) = 0;
- body.m_body_ang_acc_rel(2) = 0;
- break;
- case FIXED:
- body.m_parent_pos_parent_body = body.m_parent_pos_parent_body_ref;
- body.m_body_T_parent = body.m_body_T_parent_ref;
- body.m_body_ang_vel_rel(0) = 0;
- body.m_body_ang_vel_rel(1) = 0;
- body.m_body_ang_vel_rel(2) = 0;
- body.m_parent_vel_rel(0) = 0;
- body.m_parent_vel_rel(1) = 0;
- body.m_parent_vel_rel(2) = 0;
- body.m_body_ang_acc_rel(0) = 0;
- body.m_body_ang_acc_rel(1) = 0;
- body.m_body_ang_acc_rel(2) = 0;
- body.m_parent_acc_rel(0) = 0;
- body.m_parent_acc_rel(1) = 0;
- body.m_parent_acc_rel(2) = 0;
- break;
- case FLOATING:
- // no static data
- break;
- }
-
- // resize & initialize jacobians to zero.
-#if (defined BT_ID_HAVE_MAT3X) && (defined BT_ID_WITH_JACOBIANS)
- body.m_body_dot_Jac_T_u(0) = 0.0;
- body.m_body_dot_Jac_T_u(1) = 0.0;
- body.m_body_dot_Jac_T_u(2) = 0.0;
- body.m_body_dot_Jac_R_u(0) = 0.0;
- body.m_body_dot_Jac_R_u(1) = 0.0;
- body.m_body_dot_Jac_R_u(2) = 0.0;
- resize(body.m_body_Jac_T,m_num_dofs);
- resize(body.m_body_Jac_R,m_num_dofs);
- body.m_body_Jac_T.setZero();
- body.m_body_Jac_R.setZero();
-#endif //
- }
-}
-
-int MultiBodyTree::MultiBodyImpl::calculateInverseDynamics(const vecx &q, const vecx &u,
- const vecx &dot_u, vecx *joint_forces) {
- if (q.size() != m_num_dofs || u.size() != m_num_dofs || dot_u.size() != m_num_dofs ||
- joint_forces->size() != m_num_dofs) {
- error_message("wrong vector dimension. system has %d DOFs,\n"
- "but dim(q)= %d, dim(u)= %d, dim(dot_u)= %d, dim(joint_forces)= %d\n",
- m_num_dofs, static_cast<int>(q.size()), static_cast<int>(u.size()),
- static_cast<int>(dot_u.size()), static_cast<int>(joint_forces->size()));
- return -1;
- }
- // 1. relative kinematics
- if(-1 == calculateKinematics(q,u,dot_u, POSITION_VELOCITY_ACCELERATION)) {
- error_message("error in calculateKinematics\n");
- return -1;
- }
- // 2. update contributions to equations of motion for every body.
- for (idArrayIdx i = 0; i < m_body_list.size(); i++) {
- RigidBody &body = m_body_list[i];
- // 3.4 update dynamic terms (rate of change of angular & linear momentum)
- body.m_eom_lhs_rotational =
- body.m_body_I_body * body.m_body_ang_acc + body.m_body_mass_com.cross(body.m_body_acc) +
- body.m_body_ang_vel.cross(body.m_body_I_body * body.m_body_ang_vel) -
- body.m_body_moment_user;
- body.m_eom_lhs_translational =
- body.m_body_ang_acc.cross(body.m_body_mass_com) + body.m_mass * body.m_body_acc +
- body.m_body_ang_vel.cross(body.m_body_ang_vel.cross(body.m_body_mass_com)) -
- body.m_body_force_user;
- }
-
- // 3. calculate full set of forces at parent joint
- // (not directly calculating the joint force along the free direction
- // simplifies inclusion of fixed joints.
- // An alternative would be to fuse bodies in a pre-processing step,
- // but that would make changing masses online harder (eg, payload masses
- // added with fixed joints to a gripper)
- // Also, this enables adding zero weight bodies as a way to calculate frame poses
- // for force elements, etc.
-
- for (int body_idx = m_body_list.size() - 1; body_idx >= 0; body_idx--) {
- // sum of forces and moments acting on this body from its children
- vec3 sum_f_children;
- vec3 sum_m_children;
- setZero(sum_f_children);
- setZero(sum_m_children);
- for (idArrayIdx child_list_idx = 0; child_list_idx < m_child_indices[body_idx].size();
- child_list_idx++) {
- const RigidBody &child = m_body_list[m_child_indices[body_idx][child_list_idx]];
- vec3 child_joint_force_in_this_frame =
- child.m_body_T_parent.transpose() * child.m_force_at_joint;
- sum_f_children -= child_joint_force_in_this_frame;
- sum_m_children -= child.m_body_T_parent.transpose() * child.m_moment_at_joint +
- child.m_parent_pos_parent_body.cross(child_joint_force_in_this_frame);
- }
- RigidBody &body = m_body_list[body_idx];
-
- body.m_force_at_joint = body.m_eom_lhs_translational - sum_f_children;
- body.m_moment_at_joint = body.m_eom_lhs_rotational - sum_m_children;
- }
-
- // 4. Calculate Joint forces.
- // These are the components of force_at_joint/moment_at_joint
- // in the free directions given by Jac_JT/Jac_JR
- // 4.1 revolute joints
- for (idArrayIdx i = 0; i < m_body_revolute_list.size(); i++) {
- RigidBody &body = m_body_list[m_body_revolute_list[i]];
- // (*joint_forces)(body.m_q_index) = body.m_Jac_JR.transpose() * body.m_moment_at_joint;
- (*joint_forces)(body.m_q_index) = body.m_Jac_JR.dot(body.m_moment_at_joint);
- }
- // 4.2 for prismatic joints
- for (idArrayIdx i = 0; i < m_body_prismatic_list.size(); i++) {
- RigidBody &body = m_body_list[m_body_prismatic_list[i]];
- // (*joint_forces)(body.m_q_index) = body.m_Jac_JT.transpose() * body.m_force_at_joint;
- (*joint_forces)(body.m_q_index) = body.m_Jac_JT.dot(body.m_force_at_joint);
- }
- // 4.3 floating bodies (6-DoF joints)
- for (idArrayIdx i = 0; i < m_body_floating_list.size(); i++) {
- RigidBody &body = m_body_list[m_body_floating_list[i]];
- (*joint_forces)(body.m_q_index + 0) = body.m_moment_at_joint(0);
- (*joint_forces)(body.m_q_index + 1) = body.m_moment_at_joint(1);
- (*joint_forces)(body.m_q_index + 2) = body.m_moment_at_joint(2);
-
- (*joint_forces)(body.m_q_index + 3) = body.m_force_at_joint(0);
- (*joint_forces)(body.m_q_index + 4) = body.m_force_at_joint(1);
- (*joint_forces)(body.m_q_index + 5) = body.m_force_at_joint(2);
- }
-
- return 0;
-}
-
-int MultiBodyTree::MultiBodyImpl::calculateKinematics(const vecx &q, const vecx &u, const vecx& dot_u,
- const KinUpdateType type) {
- if (q.size() != m_num_dofs || u.size() != m_num_dofs || dot_u.size() != m_num_dofs ) {
- error_message("wrong vector dimension. system has %d DOFs,\n"
- "but dim(q)= %d, dim(u)= %d, dim(dot_u)= %d\n",
- m_num_dofs, static_cast<int>(q.size()), static_cast<int>(u.size()),
- static_cast<int>(dot_u.size()));
- return -1;
- }
- if(type != POSITION_ONLY && type != POSITION_VELOCITY && type != POSITION_VELOCITY_ACCELERATION) {
- error_message("invalid type %d\n", type);
- return -1;
- }
-
- // 1. update relative kinematics
- // 1.1 for revolute
- for (idArrayIdx i = 0; i < m_body_revolute_list.size(); i++) {
- RigidBody &body = m_body_list[m_body_revolute_list[i]];
- mat33 T;
- bodyTParentFromAxisAngle(body.m_Jac_JR, q(body.m_q_index), &T);
- body.m_body_T_parent = T * body.m_body_T_parent_ref;
- if(type >= POSITION_VELOCITY) {
- body.m_body_ang_vel_rel = body.m_Jac_JR * u(body.m_q_index);
- }
- if(type >= POSITION_VELOCITY_ACCELERATION) {
- body.m_body_ang_acc_rel = body.m_Jac_JR * dot_u(body.m_q_index);
- }
- }
- // 1.2 for prismatic
- for (idArrayIdx i = 0; i < m_body_prismatic_list.size(); i++) {
- RigidBody &body = m_body_list[m_body_prismatic_list[i]];
- body.m_parent_pos_parent_body =
- body.m_parent_pos_parent_body_ref + body.m_parent_Jac_JT * q(body.m_q_index);
- if(type >= POSITION_VELOCITY) {
- body.m_parent_vel_rel =
- body.m_body_T_parent_ref.transpose() * body.m_Jac_JT * u(body.m_q_index);
- }
- if(type >= POSITION_VELOCITY_ACCELERATION) {
- body.m_parent_acc_rel = body.m_parent_Jac_JT * dot_u(body.m_q_index);
- }
- }
- // 1.3 fixed joints: nothing to do
- // 1.4 6dof joints:
- for (idArrayIdx i = 0; i < m_body_floating_list.size(); i++) {
- RigidBody &body = m_body_list[m_body_floating_list[i]];
-
- body.m_body_T_parent = transformZ(q(body.m_q_index + 2)) *
- transformY(q(body.m_q_index + 1)) * transformX(q(body.m_q_index));
- body.m_parent_pos_parent_body(0) = q(body.m_q_index + 3);
- body.m_parent_pos_parent_body(1) = q(body.m_q_index + 4);
- body.m_parent_pos_parent_body(2) = q(body.m_q_index + 5);
- body.m_parent_pos_parent_body = body.m_body_T_parent * body.m_parent_pos_parent_body;
-
- if(type >= POSITION_VELOCITY) {
- body.m_body_ang_vel_rel(0) = u(body.m_q_index + 0);
- body.m_body_ang_vel_rel(1) = u(body.m_q_index + 1);
- body.m_body_ang_vel_rel(2) = u(body.m_q_index + 2);
-
- body.m_parent_vel_rel(0) = u(body.m_q_index + 3);
- body.m_parent_vel_rel(1) = u(body.m_q_index + 4);
- body.m_parent_vel_rel(2) = u(body.m_q_index + 5);
-
- body.m_parent_vel_rel = body.m_body_T_parent.transpose() * body.m_parent_vel_rel;
- }
- if(type >= POSITION_VELOCITY_ACCELERATION) {
- body.m_body_ang_acc_rel(0) = dot_u(body.m_q_index + 0);
- body.m_body_ang_acc_rel(1) = dot_u(body.m_q_index + 1);
- body.m_body_ang_acc_rel(2) = dot_u(body.m_q_index + 2);
-
- body.m_parent_acc_rel(0) = dot_u(body.m_q_index + 3);
- body.m_parent_acc_rel(1) = dot_u(body.m_q_index + 4);
- body.m_parent_acc_rel(2) = dot_u(body.m_q_index + 5);
-
- body.m_parent_acc_rel = body.m_body_T_parent.transpose() * body.m_parent_acc_rel;
- }
- }
-
- // 2. absolute kinematic quantities (vector valued)
- // NOTE: this should be optimized by specializing for different body types
- // (e.g., relative rotation is always zero for prismatic joints, etc.)
-
- // calculations for root body
- {
- RigidBody &body = m_body_list[0];
- // 3.1 update absolute positions and orientations:
- // will be required if we add force elements (eg springs between bodies,
- // or contacts)
- // not required right now, added here for debugging purposes
- body.m_body_pos = body.m_body_T_parent * body.m_parent_pos_parent_body;
- body.m_body_T_world = body.m_body_T_parent;
-
- if(type >= POSITION_VELOCITY) {
- // 3.2 update absolute velocities
- body.m_body_ang_vel = body.m_body_ang_vel_rel;
- body.m_body_vel = body.m_parent_vel_rel;
- }
- if(type >= POSITION_VELOCITY_ACCELERATION) {
- // 3.3 update absolute accelerations
- // NOTE: assumption: dot(J_JR) = 0; true here, but not for general joints
- body.m_body_ang_acc = body.m_body_ang_acc_rel;
- body.m_body_acc = body.m_body_T_parent * body.m_parent_acc_rel;
- // add gravitational acceleration to root body
- // this is an efficient way to add gravitational terms,
- // but it does mean that the kinematics are no longer
- // correct at the acceleration level
- // NOTE: To get correct acceleration kinematics, just set world_gravity to zero
- body.m_body_acc = body.m_body_acc - body.m_body_T_parent * m_world_gravity;
- }
- }
-
- for (idArrayIdx i = 1; i < m_body_list.size(); i++) {
- RigidBody &body = m_body_list[i];
- RigidBody &parent = m_body_list[m_parent_index[i]];
- // 2.1 update absolute positions and orientations:
- // will be required if we add force elements (eg springs between bodies,
- // or contacts) not required right now added here for debugging purposes
- body.m_body_pos =
- body.m_body_T_parent * (parent.m_body_pos + body.m_parent_pos_parent_body);
- body.m_body_T_world = body.m_body_T_parent * parent.m_body_T_world;
-
- if(type >= POSITION_VELOCITY) {
- // 2.2 update absolute velocities
- body.m_body_ang_vel =
- body.m_body_T_parent * parent.m_body_ang_vel + body.m_body_ang_vel_rel;
-
- body.m_body_vel =
- body.m_body_T_parent *
- (parent.m_body_vel + parent.m_body_ang_vel.cross(body.m_parent_pos_parent_body) +
- body.m_parent_vel_rel);
- }
- if(type >= POSITION_VELOCITY_ACCELERATION) {
- // 2.3 update absolute accelerations
- // NOTE: assumption: dot(J_JR) = 0; true here, but not for general joints
- body.m_body_ang_acc =
- body.m_body_T_parent * parent.m_body_ang_acc -
- body.m_body_ang_vel_rel.cross(body.m_body_T_parent * parent.m_body_ang_vel) +
- body.m_body_ang_acc_rel;
- body.m_body_acc =
- body.m_body_T_parent *
- (parent.m_body_acc + parent.m_body_ang_acc.cross(body.m_parent_pos_parent_body) +
- parent.m_body_ang_vel.cross(parent.m_body_ang_vel.cross(body.m_parent_pos_parent_body)) +
- 2.0 * parent.m_body_ang_vel.cross(body.m_parent_vel_rel) + body.m_parent_acc_rel);
- }
- }
-
- return 0;
-}
-
-#if (defined BT_ID_HAVE_MAT3X) && (defined BT_ID_WITH_JACOBIANS)
-
-void MultiBodyTree::MultiBodyImpl::addRelativeJacobianComponent(RigidBody&body) {
- const int& idx=body.m_q_index;
- switch(body.m_joint_type) {
- case FIXED:
- break;
- case REVOLUTE:
- setMat3xElem(0,idx, body.m_Jac_JR(0), &body.m_body_Jac_R);
- setMat3xElem(1,idx, body.m_Jac_JR(1), &body.m_body_Jac_R);
- setMat3xElem(2,idx, body.m_Jac_JR(2), &body.m_body_Jac_R);
- break;
- case PRISMATIC:
- setMat3xElem(0,idx, body.m_body_T_parent_ref(0,0)*body.m_Jac_JT(0)
- +body.m_body_T_parent_ref(1,0)*body.m_Jac_JT(1)
- +body.m_body_T_parent_ref(2,0)*body.m_Jac_JT(2),
- &body.m_body_Jac_T);
- setMat3xElem(1,idx,body.m_body_T_parent_ref(0,1)*body.m_Jac_JT(0)
- +body.m_body_T_parent_ref(1,1)*body.m_Jac_JT(1)
- +body.m_body_T_parent_ref(2,1)*body.m_Jac_JT(2),
- &body.m_body_Jac_T);
- setMat3xElem(2,idx, body.m_body_T_parent_ref(0,2)*body.m_Jac_JT(0)
- +body.m_body_T_parent_ref(1,2)*body.m_Jac_JT(1)
- +body.m_body_T_parent_ref(2,2)*body.m_Jac_JT(2),
- &body.m_body_Jac_T);
- break;
- case FLOATING:
- setMat3xElem(0,idx+0, 1.0, &body.m_body_Jac_R);
- setMat3xElem(1,idx+1, 1.0, &body.m_body_Jac_R);
- setMat3xElem(2,idx+2, 1.0, &body.m_body_Jac_R);
- // body_Jac_T = body_T_parent.transpose();
- setMat3xElem(0,idx+3, body.m_body_T_parent(0,0), &body.m_body_Jac_T);
- setMat3xElem(0,idx+4, body.m_body_T_parent(1,0), &body.m_body_Jac_T);
- setMat3xElem(0,idx+5, body.m_body_T_parent(2,0), &body.m_body_Jac_T);
-
- setMat3xElem(1,idx+3, body.m_body_T_parent(0,1), &body.m_body_Jac_T);
- setMat3xElem(1,idx+4, body.m_body_T_parent(1,1), &body.m_body_Jac_T);
- setMat3xElem(1,idx+5, body.m_body_T_parent(2,1), &body.m_body_Jac_T);
-
- setMat3xElem(2,idx+3, body.m_body_T_parent(0,2), &body.m_body_Jac_T);
- setMat3xElem(2,idx+4, body.m_body_T_parent(1,2), &body.m_body_Jac_T);
- setMat3xElem(2,idx+5, body.m_body_T_parent(2,2), &body.m_body_Jac_T);
-
- break;
- }
-}
-
-int MultiBodyTree::MultiBodyImpl::calculateJacobians(const vecx& q, const vecx& u, const KinUpdateType type) {
- if (q.size() != m_num_dofs || u.size() != m_num_dofs) {
- error_message("wrong vector dimension. system has %d DOFs,\n"
- "but dim(q)= %d, dim(u)= %d\n",
- m_num_dofs, static_cast<int>(q.size()), static_cast<int>(u.size()));
- return -1;
- }
- if(type != POSITION_ONLY && type != POSITION_VELOCITY) {
- error_message("invalid type %d\n", type);
- return -1;
- }
-
- addRelativeJacobianComponent(m_body_list[0]);
- for (idArrayIdx i = 1; i < m_body_list.size(); i++) {
- RigidBody &body = m_body_list[i];
- RigidBody &parent = m_body_list[m_parent_index[i]];
-
- mul(body.m_body_T_parent, parent.m_body_Jac_R,& body.m_body_Jac_R);
- body.m_body_Jac_T = parent.m_body_Jac_T;
- mul(tildeOperator(body.m_parent_pos_parent_body),parent.m_body_Jac_R,&m_m3x);
- sub(body.m_body_Jac_T,m_m3x, &body.m_body_Jac_T);
-
- addRelativeJacobianComponent(body);
- mul(body.m_body_T_parent, body.m_body_Jac_T,&body.m_body_Jac_T);
-
- if(type >= POSITION_VELOCITY) {
- body.m_body_dot_Jac_R_u = body.m_body_T_parent * parent.m_body_dot_Jac_R_u -
- body.m_body_ang_vel_rel.cross(body.m_body_T_parent * parent.m_body_ang_vel);
- body.m_body_dot_Jac_T_u = body.m_body_T_parent *
- (parent.m_body_dot_Jac_T_u + parent.m_body_dot_Jac_R_u.cross(body.m_parent_pos_parent_body) +
- parent.m_body_ang_vel.cross(parent.m_body_ang_vel.cross(body.m_parent_pos_parent_body)) +
- 2.0 * parent.m_body_ang_vel.cross(body.m_parent_vel_rel));
- }
- }
- return 0;
-}
-#endif
-
-static inline void setSixDoFJacobians(const int dof, vec3 &Jac_JR, vec3 &Jac_JT) {
- switch (dof) {
- // rotational part
- case 0:
- Jac_JR(0) = 1;
- Jac_JR(1) = 0;
- Jac_JR(2) = 0;
- setZero(Jac_JT);
- break;
- case 1:
- Jac_JR(0) = 0;
- Jac_JR(1) = 1;
- Jac_JR(2) = 0;
- setZero(Jac_JT);
- break;
- case 2:
- Jac_JR(0) = 0;
- Jac_JR(1) = 0;
- Jac_JR(2) = 1;
- setZero(Jac_JT);
- break;
- // translational part
- case 3:
- setZero(Jac_JR);
- Jac_JT(0) = 1;
- Jac_JT(1) = 0;
- Jac_JT(2) = 0;
- break;
- case 4:
- setZero(Jac_JR);
- Jac_JT(0) = 0;
- Jac_JT(1) = 1;
- Jac_JT(2) = 0;
- break;
- case 5:
- setZero(Jac_JR);
- Jac_JT(0) = 0;
- Jac_JT(1) = 0;
- Jac_JT(2) = 1;
- break;
- }
-}
-
-static inline int jointNumDoFs(const JointType &type) {
- switch (type) {
- case FIXED:
- return 0;
- case REVOLUTE:
- case PRISMATIC:
- return 1;
- case FLOATING:
- return 6;
- }
- // this should never happen
- error_message("invalid joint type\n");
- // TODO add configurable abort/crash function
- abort();
- return 0;
-}
-
-int MultiBodyTree::MultiBodyImpl::calculateMassMatrix(const vecx &q, const bool update_kinematics,
- const bool initialize_matrix,
- const bool set_lower_triangular_matrix,
- matxx *mass_matrix) {
-// This calculates the joint space mass matrix for the multibody system.
-// The algorithm is essentially an implementation of "method 3"
-// in "Efficient Dynamic Simulation of Robotic Mechanisms" (Walker and Orin, 1982)
-// (Later named "Composite Rigid Body Algorithm" by Featherstone).
-//
-// This implementation, however, handles branched systems and uses a formulation centered
-// on the origin of the body-fixed frame to avoid re-computing various quantities at the com.
-
- if (q.size() != m_num_dofs || mass_matrix->rows() != m_num_dofs ||
- mass_matrix->cols() != m_num_dofs) {
- error_message("Dimension error. System has %d DOFs,\n"
- "but dim(q)= %d, dim(mass_matrix)= %d x %d\n",
- m_num_dofs, static_cast<int>(q.size()), static_cast<int>(mass_matrix->rows()),
- static_cast<int>(mass_matrix->cols()));
- return -1;
- }
-
- // TODO add optimized zeroing function?
- if (initialize_matrix) {
- for (int i = 0; i < m_num_dofs; i++) {
- for (int j = 0; j < m_num_dofs; j++) {
- setMatxxElem(i, j, 0.0, mass_matrix);
- }
- }
- }
-
- if (update_kinematics) {
- // 1. update relative kinematics
- // 1.1 for revolute joints
- for (idArrayIdx i = 0; i < m_body_revolute_list.size(); i++) {
- RigidBody &body = m_body_list[m_body_revolute_list[i]];
- // from reference orientation (q=0) of body-fixed frame to current orientation
- mat33 body_T_body_ref;
- bodyTParentFromAxisAngle(body.m_Jac_JR, q(body.m_q_index), &body_T_body_ref);
- body.m_body_T_parent = body_T_body_ref * body.m_body_T_parent_ref;
- }
- // 1.2 for prismatic joints
- for (idArrayIdx i = 0; i < m_body_prismatic_list.size(); i++) {
- RigidBody &body = m_body_list[m_body_prismatic_list[i]];
- // body.m_body_T_parent= fixed
- body.m_parent_pos_parent_body =
- body.m_parent_pos_parent_body_ref + body.m_parent_Jac_JT * q(body.m_q_index);
- }
- // 1.3 fixed joints: nothing to do
- // 1.4 6dof joints:
- for (idArrayIdx i = 0; i < m_body_floating_list.size(); i++) {
- RigidBody &body = m_body_list[m_body_floating_list[i]];
-
- body.m_body_T_parent = transformZ(q(body.m_q_index + 2)) *
- transformY(q(body.m_q_index + 1)) *
- transformX(q(body.m_q_index));
- body.m_parent_pos_parent_body(0) = q(body.m_q_index + 3);
- body.m_parent_pos_parent_body(1) = q(body.m_q_index + 4);
- body.m_parent_pos_parent_body(2) = q(body.m_q_index + 5);
-
- body.m_parent_pos_parent_body = body.m_body_T_parent * body.m_parent_pos_parent_body;
- }
- }
- for (int i = m_body_list.size() - 1; i >= 0; i--) {
- RigidBody &body = m_body_list[i];
- // calculate mass, center of mass and inertia of "composite rigid body",
- // ie, sub-tree starting at current body
- body.m_subtree_mass = body.m_mass;
- body.m_body_subtree_mass_com = body.m_body_mass_com;
- body.m_body_subtree_I_body = body.m_body_I_body;
-
- for (idArrayIdx c = 0; c < m_child_indices[i].size(); c++) {
- RigidBody &child = m_body_list[m_child_indices[i][c]];
- mat33 body_T_child = child.m_body_T_parent.transpose();
-
- body.m_subtree_mass += child.m_subtree_mass;
- body.m_body_subtree_mass_com += body_T_child * child.m_body_subtree_mass_com +
- child.m_parent_pos_parent_body * child.m_subtree_mass;
- body.m_body_subtree_I_body +=
- body_T_child * child.m_body_subtree_I_body * child.m_body_T_parent;
-
- if (child.m_subtree_mass > 0) {
- // Shift the reference point for the child subtree inertia using the
- // Huygens-Steiner ("parallel axis") theorem.
- // (First shift from child origin to child com, then from there to this body's
- // origin)
- vec3 r_com = body_T_child * child.m_body_subtree_mass_com / child.m_subtree_mass;
- mat33 tilde_r_child_com = tildeOperator(r_com);
- mat33 tilde_r_body_com = tildeOperator(child.m_parent_pos_parent_body + r_com);
- body.m_body_subtree_I_body +=
- child.m_subtree_mass *
- (tilde_r_child_com * tilde_r_child_com - tilde_r_body_com * tilde_r_body_com);
- }
- }
- }
-
- for (int i = m_body_list.size() - 1; i >= 0; i--) {
- const RigidBody &body = m_body_list[i];
-
- // determine DoF-range for body
- const int q_index_min = body.m_q_index;
- const int q_index_max = q_index_min + jointNumDoFs(body.m_joint_type) - 1;
- // loop over the DoFs used by this body
- // local joint jacobians (ok as is for 1-DoF joints)
- vec3 Jac_JR = body.m_Jac_JR;
- vec3 Jac_JT = body.m_Jac_JT;
- for (int col = q_index_max; col >= q_index_min; col--) {
- // set jacobians for 6-DoF joints
- if (FLOATING == body.m_joint_type) {
- setSixDoFJacobians(col - q_index_min, Jac_JR, Jac_JT);
- }
-
- vec3 body_eom_rot =
- body.m_body_subtree_I_body * Jac_JR + body.m_body_subtree_mass_com.cross(Jac_JT);
- vec3 body_eom_trans =
- body.m_subtree_mass * Jac_JT - body.m_body_subtree_mass_com.cross(Jac_JR);
- setMatxxElem(col, col, Jac_JR.dot(body_eom_rot) + Jac_JT.dot(body_eom_trans), mass_matrix);
-
- // rest of the mass matrix column upwards
- {
- // 1. for multi-dof joints, rest of the dofs of this body
- for (int row = col - 1; row >= q_index_min; row--) {
- if (FLOATING != body.m_joint_type) {
- error_message("??\n");
- return -1;
- }
- setSixDoFJacobians(row - q_index_min, Jac_JR, Jac_JT);
- const double Mrc = Jac_JR.dot(body_eom_rot) + Jac_JT.dot(body_eom_trans);
- setMatxxElem(col, row, Mrc, mass_matrix);
- }
- // 2. ancestor dofs
- int child_idx = i;
- int parent_idx = m_parent_index[i];
- while (parent_idx >= 0) {
- const RigidBody &child_body = m_body_list[child_idx];
- const RigidBody &parent_body = m_body_list[parent_idx];
-
- const mat33 parent_T_child = child_body.m_body_T_parent.transpose();
- body_eom_rot = parent_T_child * body_eom_rot;
- body_eom_trans = parent_T_child * body_eom_trans;
- body_eom_rot += child_body.m_parent_pos_parent_body.cross(body_eom_trans);
-
- const int parent_body_q_index_min = parent_body.m_q_index;
- const int parent_body_q_index_max =
- parent_body_q_index_min + jointNumDoFs(parent_body.m_joint_type) - 1;
- vec3 Jac_JR = parent_body.m_Jac_JR;
- vec3 Jac_JT = parent_body.m_Jac_JT;
- for (int row = parent_body_q_index_max; row >= parent_body_q_index_min; row--) {
- // set jacobians for 6-DoF joints
- if (FLOATING == parent_body.m_joint_type) {
- setSixDoFJacobians(row - parent_body_q_index_min, Jac_JR, Jac_JT);
- }
- const double Mrc = Jac_JR.dot(body_eom_rot) + Jac_JT.dot(body_eom_trans);
- setMatxxElem(col, row, Mrc, mass_matrix);
- }
-
- child_idx = parent_idx;
- parent_idx = m_parent_index[child_idx];
- }
- }
- }
- }
-
- if (set_lower_triangular_matrix) {
- for (int col = 0; col < m_num_dofs; col++) {
- for (int row = 0; row < col; row++) {
- setMatxxElem(row, col, (*mass_matrix)(col, row), mass_matrix);
- }
- }
- }
- return 0;
-}
-
-// utility macro
-#define CHECK_IF_BODY_INDEX_IS_VALID(index) \
- do { \
- if (index < 0 || index >= m_num_bodies) { \
- error_message("invalid index %d (num_bodies= %d)\n", index, m_num_bodies); \
- return -1; \
- } \
- } while (0)
-
-int MultiBodyTree::MultiBodyImpl::getParentIndex(const int body_index, int *p) {
- CHECK_IF_BODY_INDEX_IS_VALID(body_index);
- *p = m_parent_index[body_index];
- return 0;
-}
-
-int MultiBodyTree::MultiBodyImpl::getUserInt(const int body_index, int *user_int) const {
- CHECK_IF_BODY_INDEX_IS_VALID(body_index);
- *user_int = m_user_int[body_index];
- return 0;
-}
-int MultiBodyTree::MultiBodyImpl::getUserPtr(const int body_index, void **user_ptr) const {
- CHECK_IF_BODY_INDEX_IS_VALID(body_index);
- *user_ptr = m_user_ptr[body_index];
- return 0;
-}
-
-int MultiBodyTree::MultiBodyImpl::setUserInt(const int body_index, const int user_int) {
- CHECK_IF_BODY_INDEX_IS_VALID(body_index);
- m_user_int[body_index] = user_int;
- return 0;
-}
-
-int MultiBodyTree::MultiBodyImpl::setUserPtr(const int body_index, void *const user_ptr) {
- CHECK_IF_BODY_INDEX_IS_VALID(body_index);
- m_user_ptr[body_index] = user_ptr;
- return 0;
-}
-
-int MultiBodyTree::MultiBodyImpl::getBodyOrigin(int body_index, vec3 *world_origin) const {
- CHECK_IF_BODY_INDEX_IS_VALID(body_index);
- const RigidBody &body = m_body_list[body_index];
- *world_origin = body.m_body_T_world.transpose() * body.m_body_pos;
- return 0;
-}
-
-int MultiBodyTree::MultiBodyImpl::getBodyCoM(int body_index, vec3 *world_com) const {
- CHECK_IF_BODY_INDEX_IS_VALID(body_index);
- const RigidBody &body = m_body_list[body_index];
- if (body.m_mass > 0) {
- *world_com = body.m_body_T_world.transpose() *
- (body.m_body_pos + body.m_body_mass_com / body.m_mass);
- } else {
- *world_com = body.m_body_T_world.transpose() * (body.m_body_pos);
- }
- return 0;
-}
-
-int MultiBodyTree::MultiBodyImpl::getBodyTransform(int body_index, mat33 *world_T_body) const {
- CHECK_IF_BODY_INDEX_IS_VALID(body_index);
- const RigidBody &body = m_body_list[body_index];
- *world_T_body = body.m_body_T_world.transpose();
- return 0;
-}
-int MultiBodyTree::MultiBodyImpl::getBodyAngularVelocity(int body_index, vec3 *world_omega) const {
- CHECK_IF_BODY_INDEX_IS_VALID(body_index);
- const RigidBody &body = m_body_list[body_index];
- *world_omega = body.m_body_T_world.transpose() * body.m_body_ang_vel;
- return 0;
-}
-int MultiBodyTree::MultiBodyImpl::getBodyLinearVelocity(int body_index,
- vec3 *world_velocity) const {
- CHECK_IF_BODY_INDEX_IS_VALID(body_index);
- const RigidBody &body = m_body_list[body_index];
- *world_velocity = body.m_body_T_world.transpose() * body.m_body_vel;
- return 0;
-}
-
-int MultiBodyTree::MultiBodyImpl::getBodyLinearVelocityCoM(int body_index,
- vec3 *world_velocity) const {
- CHECK_IF_BODY_INDEX_IS_VALID(body_index);
- const RigidBody &body = m_body_list[body_index];
- vec3 com;
- if (body.m_mass > 0) {
- com = body.m_body_mass_com / body.m_mass;
- } else {
- com(0) = 0;
- com(1) = 0;
- com(2) = 0;
- }
-
- *world_velocity =
- body.m_body_T_world.transpose() * (body.m_body_vel + body.m_body_ang_vel.cross(com));
- return 0;
-}
-
-int MultiBodyTree::MultiBodyImpl::getBodyAngularAcceleration(int body_index,
- vec3 *world_dot_omega) const {
- CHECK_IF_BODY_INDEX_IS_VALID(body_index);
- const RigidBody &body = m_body_list[body_index];
- *world_dot_omega = body.m_body_T_world.transpose() * body.m_body_ang_acc;
- return 0;
-}
-int MultiBodyTree::MultiBodyImpl::getBodyLinearAcceleration(int body_index,
- vec3 *world_acceleration) const {
- CHECK_IF_BODY_INDEX_IS_VALID(body_index);
- const RigidBody &body = m_body_list[body_index];
- *world_acceleration = body.m_body_T_world.transpose() * body.m_body_acc;
- return 0;
-}
-
-int MultiBodyTree::MultiBodyImpl::getJointType(const int body_index, JointType *joint_type) const {
- CHECK_IF_BODY_INDEX_IS_VALID(body_index);
- *joint_type = m_body_list[body_index].m_joint_type;
- return 0;
-}
-
-int MultiBodyTree::MultiBodyImpl::getJointTypeStr(const int body_index,
- const char **joint_type) const {
- CHECK_IF_BODY_INDEX_IS_VALID(body_index);
- *joint_type = jointTypeToString(m_body_list[body_index].m_joint_type);
- return 0;
-}
-
-int MultiBodyTree::MultiBodyImpl::getParentRParentBodyRef(const int body_index, vec3* r) const{
- CHECK_IF_BODY_INDEX_IS_VALID(body_index);
- *r=m_body_list[body_index].m_parent_pos_parent_body_ref;
- return 0;
-}
-
-int MultiBodyTree::MultiBodyImpl::getBodyTParentRef(const int body_index, mat33* T) const{
- CHECK_IF_BODY_INDEX_IS_VALID(body_index);
- *T=m_body_list[body_index].m_body_T_parent_ref;
- return 0;
-}
-
-int MultiBodyTree::MultiBodyImpl::getBodyAxisOfMotion(const int body_index, vec3* axis) const{
- CHECK_IF_BODY_INDEX_IS_VALID(body_index);
- if(m_body_list[body_index].m_joint_type == REVOLUTE) {
- *axis = m_body_list[body_index].m_Jac_JR;
- return 0;
- }
- if(m_body_list[body_index].m_joint_type == PRISMATIC) {
- *axis = m_body_list[body_index].m_Jac_JT;
- return 0;
- }
- setZero(*axis);
- return 0;
-}
-
-int MultiBodyTree::MultiBodyImpl::getDoFOffset(const int body_index, int *q_index) const {
- CHECK_IF_BODY_INDEX_IS_VALID(body_index);
- *q_index = m_body_list[body_index].m_q_index;
- return 0;
-}
-
-int MultiBodyTree::MultiBodyImpl::setBodyMass(const int body_index, const idScalar mass) {
- CHECK_IF_BODY_INDEX_IS_VALID(body_index);
- m_body_list[body_index].m_mass = mass;
- return 0;
-}
-
-int MultiBodyTree::MultiBodyImpl::setBodyFirstMassMoment(const int body_index,
- const vec3& first_mass_moment) {
- CHECK_IF_BODY_INDEX_IS_VALID(body_index);
- m_body_list[body_index].m_body_mass_com = first_mass_moment;
- return 0;
-}
-int MultiBodyTree::MultiBodyImpl::setBodySecondMassMoment(const int body_index,
- const mat33& second_mass_moment) {
- CHECK_IF_BODY_INDEX_IS_VALID(body_index);
- m_body_list[body_index].m_body_I_body = second_mass_moment;
- return 0;
-}
-int MultiBodyTree::MultiBodyImpl::getBodyMass(const int body_index, idScalar *mass) const {
- CHECK_IF_BODY_INDEX_IS_VALID(body_index);
- *mass = m_body_list[body_index].m_mass;
- return 0;
-}
-int MultiBodyTree::MultiBodyImpl::getBodyFirstMassMoment(const int body_index,
- vec3 *first_mass_moment) const {
- CHECK_IF_BODY_INDEX_IS_VALID(body_index);
- *first_mass_moment = m_body_list[body_index].m_body_mass_com;
- return 0;
-}
-int MultiBodyTree::MultiBodyImpl::getBodySecondMassMoment(const int body_index,
- mat33 *second_mass_moment) const {
- CHECK_IF_BODY_INDEX_IS_VALID(body_index);
- *second_mass_moment = m_body_list[body_index].m_body_I_body;
- return 0;
-}
-
-void MultiBodyTree::MultiBodyImpl::clearAllUserForcesAndMoments() {
- for (int index = 0; index < m_num_bodies; index++) {
- RigidBody &body = m_body_list[index];
- setZero(body.m_body_force_user);
- setZero(body.m_body_moment_user);
- }
-}
-
-int MultiBodyTree::MultiBodyImpl::addUserForce(const int body_index, const vec3 &body_force) {
- CHECK_IF_BODY_INDEX_IS_VALID(body_index);
- m_body_list[body_index].m_body_force_user += body_force;
- return 0;
-}
-
-int MultiBodyTree::MultiBodyImpl::addUserMoment(const int body_index, const vec3 &body_moment) {
- CHECK_IF_BODY_INDEX_IS_VALID(body_index);
- m_body_list[body_index].m_body_moment_user += body_moment;
- return 0;
-}
-
-#if (defined BT_ID_HAVE_MAT3X) && (defined BT_ID_WITH_JACOBIANS)
-int MultiBodyTree::MultiBodyImpl::getBodyDotJacobianTransU(const int body_index, vec3* world_dot_jac_trans_u) const {
- CHECK_IF_BODY_INDEX_IS_VALID(body_index);
- const RigidBody &body = m_body_list[body_index];
- *world_dot_jac_trans_u = body.m_body_T_world.transpose() * body.m_body_dot_Jac_T_u;
- return 0;
-}
-
-int MultiBodyTree::MultiBodyImpl::getBodyDotJacobianRotU(const int body_index, vec3* world_dot_jac_rot_u) const{
- CHECK_IF_BODY_INDEX_IS_VALID(body_index);
- const RigidBody &body = m_body_list[body_index];
- *world_dot_jac_rot_u = body.m_body_T_world.transpose() * body.m_body_dot_Jac_R_u;
- return 0;
-}
-
-int MultiBodyTree::MultiBodyImpl::getBodyJacobianTrans(const int body_index, mat3x* world_jac_trans) const{
- CHECK_IF_BODY_INDEX_IS_VALID(body_index);
- const RigidBody &body = m_body_list[body_index];
- mul(body.m_body_T_world.transpose(), body.m_body_Jac_T, world_jac_trans);
- return 0;
-}
-
-int MultiBodyTree::MultiBodyImpl::getBodyJacobianRot(const int body_index, mat3x* world_jac_rot) const{
- CHECK_IF_BODY_INDEX_IS_VALID(body_index);
- const RigidBody &body = m_body_list[body_index];
- mul(body.m_body_T_world.transpose(), body.m_body_Jac_R,world_jac_rot);
- return 0;
-}
-
-#endif
-}
diff --git a/thirdparty/bullet/src/BulletInverseDynamics/details/MultiBodyTreeImpl.hpp b/thirdparty/bullet/src/BulletInverseDynamics/details/MultiBodyTreeImpl.hpp
deleted file mode 100644
index 3efe9d0492..0000000000
--- a/thirdparty/bullet/src/BulletInverseDynamics/details/MultiBodyTreeImpl.hpp
+++ /dev/null
@@ -1,283 +0,0 @@
-// The structs and classes defined here provide a basic inverse fynamics implementation used
-// by MultiBodyTree
-// User interaction should be through MultiBodyTree
-
-#ifndef MULTI_BODY_REFERENCE_IMPL_HPP_
-#define MULTI_BODY_REFERENCE_IMPL_HPP_
-
-#include "../IDConfig.hpp"
-#include "../MultiBodyTree.hpp"
-
-namespace btInverseDynamics {
-
-/// Structure for for rigid body mass properties, connectivity and kinematic state
-/// all vectors and matrices are in body-fixed frame, if not indicated otherwise.
-/// The body-fixed frame is located in the joint connecting the body to its parent.
-struct RigidBody {
- ID_DECLARE_ALIGNED_ALLOCATOR();
- // 1 Inertial properties
- /// Mass
- idScalar m_mass;
- /// Mass times center of gravity in body-fixed frame
- vec3 m_body_mass_com;
- /// Moment of inertia w.r.t. body-fixed frame
- mat33 m_body_I_body;
-
- // 2 dynamic properties
- /// Left-hand side of the body equation of motion, translational part
- vec3 m_eom_lhs_translational;
- /// Left-hand side of the body equation of motion, rotational part
- vec3 m_eom_lhs_rotational;
- /// Force acting at the joint when the body is cut from its parent;
- /// includes impressed joint force in J_JT direction,
- /// as well as constraint force,
- /// in body-fixed frame
- vec3 m_force_at_joint;
- /// Moment acting at the joint when the body is cut from its parent;
- /// includes impressed joint moment in J_JR direction, and constraint moment
- /// in body-fixed frame
- vec3 m_moment_at_joint;
- /// external (user provided) force acting at the body-fixed frame's origin, written in that
- /// frame
- vec3 m_body_force_user;
- /// external (user provided) moment acting at the body-fixed frame's origin, written in that
- /// frame
- vec3 m_body_moment_user;
- // 3 absolute kinematic properties
- /// Position of body-fixed frame relative to world frame
- /// this is currently only for debugging purposes
- vec3 m_body_pos;
- /// Absolute velocity of body-fixed frame
- vec3 m_body_vel;
- /// Absolute acceleration of body-fixed frame
- /// NOTE: if gravitational acceleration is not zero, this is the accelation PLUS gravitational
- /// acceleration!
- vec3 m_body_acc;
- /// Absolute angular velocity
- vec3 m_body_ang_vel;
- /// Absolute angular acceleration
- /// NOTE: if gravitational acceleration is not zero, this is the accelation PLUS gravitational
- /// acceleration!
- vec3 m_body_ang_acc;
-
- // 4 relative kinematic properties.
- // these are in the parent body frame
- /// Transform from world to body-fixed frame;
- /// this is currently only for debugging purposes
- mat33 m_body_T_world;
- /// Transform from parent to body-fixed frame
- mat33 m_body_T_parent;
- /// Vector from parent to child frame in parent frame
- vec3 m_parent_pos_parent_body;
- /// Relative angular velocity
- vec3 m_body_ang_vel_rel;
- /// Relative linear velocity
- vec3 m_parent_vel_rel;
- /// Relative angular acceleration
- vec3 m_body_ang_acc_rel;
- /// Relative linear acceleration
- vec3 m_parent_acc_rel;
-
- // 5 Data describing the joint type and geometry
- /// Type of joint
- JointType m_joint_type;
- /// Position of joint frame (body-fixed frame at q=0) relative to the parent frame
- /// Components are in body-fixed frame of the parent
- vec3 m_parent_pos_parent_body_ref;
- /// Orientation of joint frame (body-fixed frame at q=0) relative to the parent frame
- mat33 m_body_T_parent_ref;
- /// Joint rotational Jacobian, ie, the partial derivative of the body-fixed frames absolute
- /// angular velocity w.r.t. the generalized velocity of this body's relative degree of freedom.
- /// For revolute joints this is the joint axis, for prismatic joints it is a null matrix.
- /// (NOTE: dimensions will have to be dynamic for additional joint types!)
- vec3 m_Jac_JR;
- /// Joint translational Jacobian, ie, the partial derivative of the body-fixed frames absolute
- /// linear velocity w.r.t. the generalized velocity of this body's relative degree of freedom.
- /// For prismatic joints this is the joint axis, for revolute joints it is a null matrix.
- /// (NOTE: dimensions might have to be dynamic for additional joint types!)
- vec3 m_Jac_JT;
- /// m_Jac_JT in the parent frame, it, m_body_T_parent_ref.transpose()*m_Jac_JT
- vec3 m_parent_Jac_JT;
- /// Start of index range for the position degree(s) of freedom describing this body's motion
- /// relative to
- /// its parent. The indices are wrt the multibody system's q-vector of generalized coordinates.
- int m_q_index;
-
- // 6 Scratch data for mass matrix computation using "composite rigid body algorithm"
- /// mass of the subtree rooted in this body
- idScalar m_subtree_mass;
- /// center of mass * mass for subtree rooted in this body, in body-fixed frame
- vec3 m_body_subtree_mass_com;
- /// moment of inertia of subtree rooted in this body, w.r.t. body origin, in body-fixed frame
- mat33 m_body_subtree_I_body;
-
-#if (defined BT_ID_HAVE_MAT3X) && (defined BT_ID_WITH_JACOBIANS)
- /// translational jacobian in body-fixed frame d(m_body_vel)/du
- mat3x m_body_Jac_T;
- /// rotationsl jacobian in body-fixed frame d(m_body_ang_vel)/du
- mat3x m_body_Jac_R;
- /// components of linear acceleration depending on u
- /// (same as is d(m_Jac_T)/dt*u)
- vec3 m_body_dot_Jac_T_u;
- /// components of angular acceleration depending on u
- /// (same as is d(m_Jac_T)/dt*u)
- vec3 m_body_dot_Jac_R_u;
-#endif
-};
-
-/// The MBS implements a tree structured multibody system
-class MultiBodyTree::MultiBodyImpl {
- friend class MultiBodyTree;
-
-public:
- ID_DECLARE_ALIGNED_ALLOCATOR();
-
- enum KinUpdateType {
- POSITION_ONLY,
- POSITION_VELOCITY,
- POSITION_VELOCITY_ACCELERATION
- };
-
- /// constructor
- /// @param num_bodies the number of bodies in the system
- /// @param num_dofs number of degrees of freedom in the system
- MultiBodyImpl(int num_bodies_, int num_dofs_);
-
- /// \copydoc MultiBodyTree::calculateInverseDynamics
- int calculateInverseDynamics(const vecx& q, const vecx& u, const vecx& dot_u,
- vecx* joint_forces);
- ///\copydoc MultiBodyTree::calculateMassMatrix
- int calculateMassMatrix(const vecx& q, const bool update_kinematics,
- const bool initialize_matrix, const bool set_lower_triangular_matrix,
- matxx* mass_matrix);
- /// calculate kinematics (vector quantities)
- /// Depending on type, update positions only, positions & velocities, or positions, velocities
- /// and accelerations.
- int calculateKinematics(const vecx& q, const vecx& u, const vecx& dot_u, const KinUpdateType type);
-#if (defined BT_ID_HAVE_MAT3X) && (defined BT_ID_WITH_JACOBIANS)
- /// calculate jacobians and (if type == POSITION_VELOCITY), also velocity-dependent accelration terms.
- int calculateJacobians(const vecx& q, const vecx& u, const KinUpdateType type);
- /// \copydoc MultiBodyTree::getBodyDotJacobianTransU
- int getBodyDotJacobianTransU(const int body_index, vec3* world_dot_jac_trans_u) const ;
- /// \copydoc MultiBodyTree::getBodyDotJacobianRotU
- int getBodyDotJacobianRotU(const int body_index, vec3* world_dot_jac_rot_u) const;
- /// \copydoc MultiBodyTree::getBodyJacobianTrans
- int getBodyJacobianTrans(const int body_index, mat3x* world_jac_trans) const ;
- /// \copydoc MultiBodyTree::getBodyJacobianRot
- int getBodyJacobianRot(const int body_index, mat3x* world_jac_rot) const;
- /// Add relative Jacobian component from motion relative to parent body
- /// @param body the body to add the Jacobian component for
- void addRelativeJacobianComponent(RigidBody&body);
-#endif
- /// generate additional index sets from the parent_index array
- /// @return -1 on error, 0 on success
- int generateIndexSets();
- /// set gravity acceleration in world frame
- /// @param gravity gravity vector in the world frame
- /// @return 0 on success, -1 on error
- int setGravityInWorldFrame(const vec3& gravity);
- /// pretty print tree
- void printTree();
- /// print tree data
- void printTreeData();
- /// initialize fixed data
- void calculateStaticData();
- /// \copydoc MultiBodyTree::getBodyFrame
- int getBodyFrame(const int index, vec3* world_origin, mat33* body_T_world) const;
- /// \copydoc MultiBodyTree::getParentIndex
- int getParentIndex(const int body_index, int* m_parent_index);
- /// \copydoc MultiBodyTree::getJointType
- int getJointType(const int body_index, JointType* joint_type) const;
- /// \copydoc MultiBodyTree::getJointTypeStr
- int getJointTypeStr(const int body_index, const char** joint_type) const;
- /// \copydoc MultiBodyTree::getParentRParentBodyRef
- int getParentRParentBodyRef(const int body_index, vec3* r) const;
- /// \copydoc MultiBodyTree::getBodyTParentRef
- int getBodyTParentRef(const int body_index, mat33* T) const;
- /// \copydoc MultiBodyTree::getBodyAxisOfMotion
- int getBodyAxisOfMotion(const int body_index, vec3* axis) const;
- /// \copydoc MultiBodyTree:getDoFOffset
- int getDoFOffset(const int body_index, int* q_index) const;
- /// \copydoc MultiBodyTree::getBodyOrigin
- int getBodyOrigin(const int body_index, vec3* world_origin) const;
- /// \copydoc MultiBodyTree::getBodyCoM
- int getBodyCoM(const int body_index, vec3* world_com) const;
- /// \copydoc MultiBodyTree::getBodyTransform
- int getBodyTransform(const int body_index, mat33* world_T_body) const;
- /// \copydoc MultiBodyTree::getBodyAngularVelocity
- int getBodyAngularVelocity(const int body_index, vec3* world_omega) const;
- /// \copydoc MultiBodyTree::getBodyLinearVelocity
- int getBodyLinearVelocity(const int body_index, vec3* world_velocity) const;
- /// \copydoc MultiBodyTree::getBodyLinearVelocityCoM
- int getBodyLinearVelocityCoM(const int body_index, vec3* world_velocity) const;
- /// \copydoc MultiBodyTree::getBodyAngularAcceleration
- int getBodyAngularAcceleration(const int body_index, vec3* world_dot_omega) const;
- /// \copydoc MultiBodyTree::getBodyLinearAcceleration
- int getBodyLinearAcceleration(const int body_index, vec3* world_acceleration) const;
- /// \copydoc MultiBodyTree::getUserInt
- int getUserInt(const int body_index, int* user_int) const;
- /// \copydoc MultiBodyTree::getUserPtr
- int getUserPtr(const int body_index, void** user_ptr) const;
- /// \copydoc MultiBodyTree::setUserInt
- int setUserInt(const int body_index, const int user_int);
- /// \copydoc MultiBodyTree::setUserPtr
- int setUserPtr(const int body_index, void* const user_ptr);
- ///\copydoc MultiBodytTree::setBodyMass
- int setBodyMass(const int body_index, const idScalar mass);
- ///\copydoc MultiBodytTree::setBodyFirstMassMoment
- int setBodyFirstMassMoment(const int body_index, const vec3& first_mass_moment);
- ///\copydoc MultiBodytTree::setBodySecondMassMoment
- int setBodySecondMassMoment(const int body_index, const mat33& second_mass_moment);
- ///\copydoc MultiBodytTree::getBodyMass
- int getBodyMass(const int body_index, idScalar* mass) const;
- ///\copydoc MultiBodytTree::getBodyFirstMassMoment
- int getBodyFirstMassMoment(const int body_index, vec3* first_mass_moment) const;
- ///\copydoc MultiBodytTree::getBodySecondMassMoment
- int getBodySecondMassMoment(const int body_index, mat33* second_mass_moment) const;
- /// \copydoc MultiBodyTree::clearAllUserForcesAndMoments
- void clearAllUserForcesAndMoments();
- /// \copydoc MultiBodyTree::addUserForce
- int addUserForce(const int body_index, const vec3& body_force);
- /// \copydoc MultiBodyTree::addUserMoment
- int addUserMoment(const int body_index, const vec3& body_moment);
-
-private:
- // debug function. print tree structure to stdout
- void printTree(int index, int indentation);
- // get string representation of JointType (for debugging)
- const char* jointTypeToString(const JointType& type) const;
- // get number of degrees of freedom from joint type
- int bodyNumDoFs(const JointType& type) const;
- // number of bodies in the system
- int m_num_bodies;
- // number of degrees of freedom
- int m_num_dofs;
- // Gravitational acceleration (in world frame)
- vec3 m_world_gravity;
- // vector of bodies in the system
- // body 0 is used as an environment body and is allways fixed.
- // The bodies are ordered such that a parent body always has an index
- // smaller than its child.
- idArray<RigidBody>::type m_body_list;
- // Parent_index[i] is the index for i's parent body in body_list.
- // This fully describes the tree.
- idArray<int>::type m_parent_index;
- // child_indices[i] contains a vector of indices of
- // all children of the i-th body
- idArray<idArray<int>::type>::type m_child_indices;
- // Indices of rotary joints
- idArray<int>::type m_body_revolute_list;
- // Indices of prismatic joints
- idArray<int>::type m_body_prismatic_list;
- // Indices of floating joints
- idArray<int>::type m_body_floating_list;
- // a user-provided integer
- idArray<int>::type m_user_int;
- // a user-provided pointer
- idArray<void*>::type m_user_ptr;
-#if (defined BT_ID_HAVE_MAT3X) && (defined BT_ID_WITH_JACOBIANS)
- mat3x m_m3x;
-#endif
-};
-}
-#endif
diff --git a/thirdparty/bullet/src/BulletInverseDynamics/details/MultiBodyTreeInitCache.cpp b/thirdparty/bullet/src/BulletInverseDynamics/details/MultiBodyTreeInitCache.cpp
deleted file mode 100644
index 47b4ab3890..0000000000
--- a/thirdparty/bullet/src/BulletInverseDynamics/details/MultiBodyTreeInitCache.cpp
+++ /dev/null
@@ -1,113 +0,0 @@
-#include "MultiBodyTreeInitCache.hpp"
-
-namespace btInverseDynamics {
-
-MultiBodyTree::InitCache::InitCache() {
- m_inertias.resize(0);
- m_joints.resize(0);
- m_num_dofs = 0;
- m_root_index=-1;
-}
-
-int MultiBodyTree::InitCache::addBody(const int body_index, const int parent_index,
- const JointType joint_type,
- const vec3& parent_r_parent_body_ref,
- const mat33& body_T_parent_ref,
- const vec3& body_axis_of_motion, const idScalar mass,
- const vec3& body_r_body_com, const mat33& body_I_body,
- const int user_int, void* user_ptr) {
- switch (joint_type) {
- case REVOLUTE:
- case PRISMATIC:
- m_num_dofs += 1;
- break;
- case FIXED:
- // does not add a degree of freedom
- // m_num_dofs+=0;
- break;
- case FLOATING:
- m_num_dofs += 6;
- break;
- default:
- error_message("unknown joint type %d\n", joint_type);
- return -1;
- }
-
- if(-1 == parent_index) {
- if(m_root_index>=0) {
- error_message("trying to add body %d as root, but already added %d as root body\n",
- body_index, m_root_index);
- return -1;
- }
- m_root_index=body_index;
- }
-
- JointData joint;
- joint.m_child = body_index;
- joint.m_parent = parent_index;
- joint.m_type = joint_type;
- joint.m_parent_pos_parent_child_ref = parent_r_parent_body_ref;
- joint.m_child_T_parent_ref = body_T_parent_ref;
- joint.m_child_axis_of_motion = body_axis_of_motion;
-
- InertiaData body;
- body.m_mass = mass;
- body.m_body_pos_body_com = body_r_body_com;
- body.m_body_I_body = body_I_body;
-
- m_inertias.push_back(body);
- m_joints.push_back(joint);
- m_user_int.push_back(user_int);
- m_user_ptr.push_back(user_ptr);
- return 0;
-}
-int MultiBodyTree::InitCache::getInertiaData(const int index, InertiaData* inertia) const {
- if (index < 0 || index > static_cast<int>(m_inertias.size())) {
- error_message("index out of range\n");
- return -1;
- }
-
- *inertia = m_inertias[index];
- return 0;
-}
-
-int MultiBodyTree::InitCache::getUserInt(const int index, int* user_int) const {
- if (index < 0 || index > static_cast<int>(m_user_int.size())) {
- error_message("index out of range\n");
- return -1;
- }
- *user_int = m_user_int[index];
- return 0;
-}
-
-int MultiBodyTree::InitCache::getUserPtr(const int index, void** user_ptr) const {
- if (index < 0 || index > static_cast<int>(m_user_ptr.size())) {
- error_message("index out of range\n");
- return -1;
- }
- *user_ptr = m_user_ptr[index];
- return 0;
-}
-
-int MultiBodyTree::InitCache::getJointData(const int index, JointData* joint) const {
- if (index < 0 || index > static_cast<int>(m_joints.size())) {
- error_message("index out of range\n");
- return -1;
- }
- *joint = m_joints[index];
- return 0;
-}
-
-int MultiBodyTree::InitCache::buildIndexSets() {
- // NOTE: This function assumes that proper indices were provided
- // User2InternalIndex from utils can be used to facilitate this.
-
- m_parent_index.resize(numBodies());
- for (idArrayIdx j = 0; j < m_joints.size(); j++) {
- const JointData& joint = m_joints[j];
- m_parent_index[joint.m_child] = joint.m_parent;
- }
-
- return 0;
-}
-}
diff --git a/thirdparty/bullet/src/BulletInverseDynamics/details/MultiBodyTreeInitCache.hpp b/thirdparty/bullet/src/BulletInverseDynamics/details/MultiBodyTreeInitCache.hpp
deleted file mode 100644
index 0d2aa4a071..0000000000
--- a/thirdparty/bullet/src/BulletInverseDynamics/details/MultiBodyTreeInitCache.hpp
+++ /dev/null
@@ -1,109 +0,0 @@
-#ifndef MULTIBODYTREEINITCACHE_HPP_
-#define MULTIBODYTREEINITCACHE_HPP_
-
-#include "../IDConfig.hpp"
-#include "../IDMath.hpp"
-#include "../MultiBodyTree.hpp"
-
-namespace btInverseDynamics {
-/// Mass properties of a rigid body
-struct InertiaData {
- ID_DECLARE_ALIGNED_ALLOCATOR();
-
- /// mass
- idScalar m_mass;
- /// vector from body-fixed frame to center of mass,
- /// in body-fixed frame, multiplied by the mass
- vec3 m_body_pos_body_com;
- /// moment of inertia w.r.t. the origin of the body-fixed
- /// frame, represented in that frame
- mat33 m_body_I_body;
-};
-
-/// Joint properties
-struct JointData {
- ID_DECLARE_ALIGNED_ALLOCATOR();
-
- /// type of joint
- JointType m_type;
- /// index of parent body
- int m_parent;
- /// index of child body
- int m_child;
- /// vector from parent's body-fixed frame to child's body-fixed
- /// frame for q=0, written in the parent's body fixed frame
- vec3 m_parent_pos_parent_child_ref;
- /// Transform matrix converting vectors written in the parent's frame
- /// into vectors written in the child's frame for q=0
- /// ie, child_vector = child_T_parent_ref * parent_vector;
- mat33 m_child_T_parent_ref;
- /// Axis of motion for 1 degree-of-freedom joints,
- /// written in the child's frame
- /// For revolute joints, the q-value is positive for a positive
- /// rotation about this axis.
- /// For prismatic joints, the q-value is positive for a positive
- /// translation is this direction.
- vec3 m_child_axis_of_motion;
-};
-
-/// Data structure to store data passed by the user.
-/// This is used in MultiBodyTree::finalize to build internal data structures.
-class MultiBodyTree::InitCache {
-public:
- ID_DECLARE_ALIGNED_ALLOCATOR();
- /// constructor
- InitCache();
- ///\copydoc MultiBodyTree::addBody
- int addBody(const int body_index, const int parent_index, const JointType joint_type,
- const vec3 &parent_r_parent_body_ref, const mat33 &body_T_parent_ref,
- const vec3 &body_axis_of_motion, idScalar mass, const vec3 &body_r_body_com,
- const mat33 &body_I_body, const int user_int, void *user_ptr);
- /// build index arrays
- /// @return 0 on success, -1 on failure
- int buildIndexSets();
- /// @return number of degrees of freedom
- int numDoFs() const { return m_num_dofs; }
- /// @return number of bodies
- int numBodies() const { return m_inertias.size(); }
- /// get inertia data for index
- /// @param index of the body
- /// @param inertia pointer for return data
- /// @return 0 on success, -1 on failure
- int getInertiaData(const int index, InertiaData *inertia) const;
- /// get joint data for index
- /// @param index of the body
- /// @param joint pointer for return data
- /// @return 0 on success, -1 on failure
- int getJointData(const int index, JointData *joint) const;
- /// get parent index array (paren_index[i] is the index of the parent of i)
- /// @param parent_index pointer for return data
- void getParentIndexArray(idArray<int>::type *parent_index) { *parent_index = m_parent_index; }
- /// get user integer
- /// @param index body index
- /// @param user_int user integer
- /// @return 0 on success, -1 on failure
- int getUserInt(const int index, int *user_int) const;
- /// get user pointer
- /// @param index body index
- /// @param user_int user pointer
- /// @return 0 on success, -1 on failure
- int getUserPtr(const int index, void **user_ptr) const;
-
-private:
- // vector of bodies
- idArray<InertiaData>::type m_inertias;
- // vector of joints
- idArray<JointData>::type m_joints;
- // number of mechanical degrees of freedom
- int m_num_dofs;
- // parent index array
- idArray<int>::type m_parent_index;
- // user integers
- idArray<int>::type m_user_int;
- // user pointers
- idArray<void *>::type m_user_ptr;
- // index of root body (or -1 if not set)
- int m_root_index;
-};
-}
-#endif // MULTIBODYTREEINITCACHE_HPP_